Systems and methods for an oven with a movable cook surface

ABSTRACT

Systems and methods for an oven include a housing, a heating chamber positioned within the housing, at least one oven door to provide access to the heating chamber, an external nesting rack positionable on or near the housing, and a movable cook surface, the movable cook surface movable between a position within the heating chamber and a position at least partially external to the heating chamber, such that when the movable cook surface is in the position at least partially external to the heating chamber, the movable cook surface is positioned at least partially recessed below a top surface of the external nesting rack. One or more heat packs can be included to provide variable forms of heat to the heating chamber.

CROSS-REFERENCES TO RELATED APPLICATIONS

This application claims priority to U.S. Provisional Application No.62/339,477 filed on May 20, 2016, and titled “Systems and Methods for anAuto-Loading Oven With a Moving Cook Surface,” which is herebyincorporated by reference.

STATEMENT REGARDING FEDERALLY SPONSORED RESEARCH

Not Applicable

BACKGROUND OF THE TECHNOLOGY

The subject matter disclosed within relates generally to cooking ovens,and more particularly to systems and methods for an oven with a movablecook surface.

For most ovens, food, or anything to be heated, is placed on a cooksurface. With some ovens, the cook surface can be moved at leastpartially outside of the heating chamber either manually or by motorizedcontrol. With the food placed on the cook surface, the cook surface isthen moved back into the heating chamber, again either manually or bymotorized control. After the food has been heated, the cook surface,along with the food positioned thereon, can then be removed from theheating chamber, again either manually or by motorized control. Not onlywill the food be hot, but the cook surface will also be hot. The exposedhot cook surface can be a concern to an operator of the oven or toothers that may inadvertently come into contact with the hot cooksurface.

What is needed is an oven where the hot cook surface can be positionedat least partially outside of the heating chamber and yet reduceexposure to contact the hot cook surface.

BRIEF SUMMARY OF THE TECHNOLOGY

The above problems can be solved by providing an oven with a movablecook surface, where the movable cook surface is positionable within orbelow an external nesting rack.

Systems and methods for an oven are disclosed. The oven can include ahousing, a heating chamber positioned within the housing, at least oneoven door to provide access to the heating chamber, an external nestingrack positionable on or near the housing, and a movable cook surface,the movable cook surface movable between a position within the heatingchamber and a position at least partially external to the heatingchamber, such that when the movable cook surface is in the positionexternal to the heating chamber, the movable cook surface is positionedat least partially recessed below a top surface of the external nestingrack. The at least partially recessed movable cook surface can bepositioned within the external nesting rack. The movable cook surfacecan include fingers and spacings between the fingers. The externalnesting rack can include support surfaces and spacings between thesupport surfaces. The fingers of the movable cook surface can movewithin the spacings between the support surfaces as the movable cooksurface is moving between the position within the heating chamber andthe position at least partially external to the heating chamber. Theexternal nesting rack is removably coupled to the housing. The externalnesting rack can move from a position below the movable cook surface toa position at least partially above the movable cook surface, such thatthe top surface of the external nesting rack is above the movable cooksurface. The heating element can heat air within a cavity fordistribution to an upper air plenum and a lower air plenum. A firstheating element can be included to provide a first method of heating.The first method of heating can provide heated air convection to theheating chamber. A second heating element can be included to provide asecond method of heating, the second method of heating being differentthan the first method of heating. The second method of heating canprovide infrared heating to the heating chamber. A user interface can beincluded, the user interface to allow individual control of the firstmethod of heating and the second method of heating.

Systems and methods for a heat pack are disclosed. The heat pack caninclude at least one heat unit, the heat unit including a trough, thetrough including an open gap between at least a first side wall and asecond side wall, the trough forming a protective housing for at leastone heating element positioned within the trough; a cover, the coverpositioned on the open gap, the cover including a first edge connectorand a second edge connector, the first edge connector to engage with thefirst side wall and the second edge connector to engage with the secondside wall, the cover including a series of perforations; and heatingelement support structure, the heating element support structure coupledto at least one of the trough and the cover, the heating element supportstructure to isolate the at least one heating element from the troughand the cover. The at least one heating element can be a resistiveheating element to provide infrared heat. The at least one heatingelement is at least one of an open coil resistive heating element, asheathed tubular resistive element, a ribbon resistive heating element,and an infrared heating lightbulb. The heating element support structurecan be a ceramic material. The heat unit can be substantially straight.A plurality of heat units can be included, each heat unit beinggenerally parallel to each other with a predetermined space between eachheat unit; and a frame, the frame to support a first end of each of theplurality of the heat units and a second end of each of the plurality ofthe heat units. Each of the plurality of heat units can be individuallycontrollable by a control system.

Systems and methods for an oven are disclosed. The oven can include ahousing; a heating chamber positioned within the housing; at least oneoven door to provide access to the heating chamber; at least one heatingelement to heat air in a cavity within the housing for distribution toan upper air plenum and a lower air plenum to provide a heated airconvection; a cook surface positioned in the heating chamber, the cooksurface to support an item for heating within the heating chamber; anupper heat pack positioned between the upper air plenum and the cooksurface to direct infrared heat downward into the heating chamber; alower heat pack positioned between the lower air plenum and the cooksurface to direct infrared heat upward into the heating chamber; theupper heat pack including a plurality of upper heat units supported byan upper frame and being generally parallel to each other with apredetermined space between each upper heat unit, each upper heat unitincluding an upper heat unit trough, the upper heat unit troughincluding an open gap between at least a first side wall and a secondside wall, the upper heat unit trough forming a protective housing forat least one upper heat unit resistive heating element positioned withinthe upper heat unit trough and supported by an upper heat unit heatingelement support structure, and an upper heat unit cover positioned onthe open gap, the upper heat unit cover including a series ofperforations; the lower heat pack including a plurality of lower heatunits supported by a lower frame and being generally parallel to eachother with a predetermined space between each lower heat unit, eachlower heat unit including a lower heat unit trough, the lower heat unittrough including an open gap between at least a first side wall and asecond side wall, the lower heat unit trough forming a protectivehousing for at least one lower heat unit resistive heating elementpositioned within the lower heat unit trough and supported by a lowerheat unit heating element support structure, and a lower heat unit coverpositioned on the open gap, the lower heat unit cover including a seriesof perforations; wherein the heated air passes through the upper airplenum and the predetermined space between each upper heat unit and intothe heating chamber such that a flow path of the heated air conventionis directed to avoid contact with the upper heat unit resistive heatingelement positioned within the upper heat unit trough; and wherein theheated air passes through the lower air plenum and the predeterminedspace between each lower heat unit and into the heating chamber suchthat the flow path of the heated air convention is directed to avoidcontact with the lower heat unit resistive heating element positionedwithin the lower heat unit trough. A user interface can be included, theuser interface to allow individual control of the upper heat pack andthe lower heat pack. The user interface can further allow individualcontrol of each upper heat unit in the upper heat pack and each lowerheat unit in the lower heat pack. The upper heat unit cover can includea first edge connector and a second edge connector, the first edgeconnector to engage with the first side wall of the upper heat unittrough and the second edge connector to engage with the second side wallof the upper heat unit trough; and the lower heat unit cover can includea first edge connector and a second edge connector, the first edgeconnector to engage with the first side wall of the lower heat unittrough and the second edge connector to engage with the second side wallof the lower heat unit trough. The upper heat unit heating elementsupport structure can be coupled to at least one of the upper heat unittrough and the upper heat unit cover, the upper heat unit heatingelement support structure to isolate the at least one upper heat unitheating element from the upper heat unit trough and the upper heat unitcover; and the lower heat unit heating element support structure can becoupled to at least one of the lower heat unit trough and the lower heatunit cover, the lower heat unit heating element support structure toisolate the at least one lower heat unit heating element from the lowerheat unit trough and the lower heat unit cover. The upper heat unitresistive heating element is at least one of an open coil resistiveheating element, a sheathed tubular resistive element, a ribbonresistive heating element, and an infrared heating lightbulb; and thelower heat unit resistive heating element is at least one of an opencoil resistive heating element, a sheathed tubular resistive element, aribbon resistive heating element, and an infrared heating lightbulb. Theupper heat unit heating element support structure can be a ceramicmaterial; and the lower heat unit heating element support structure canbe a ceramic material. An external nesting rack can be included and canbe positionable on or near the housing; and the cook surface beingmovable, the movable cook surface movable between a position within theheating chamber and a position at least partially external to theheating chamber, such that when the movable cook surface is in theposition at least partially external to the heating chamber, the movablecook surface is positioned at least partially recessed below a topsurface of the external nesting rack. A movement system can be includedto move the movable cook surface.

Systems and methods for moving an item from an oven are disclosed. Theoven can include a housing, a heating chamber positioned within thehousing, at least one oven door to provide access to the heatingchamber, an external nesting rack positionable on or near the housing,and a movable cook surface, and the method can include the steps of:moving the movable cook surface with the item on the movable cooksurface from a position within the heating chamber to a position atleast partially external to the heating chamber; and positioning themovable cook surface at least partially recessed below a top surface ofthe external nesting rack, such that the item on the movable cooksurface is no longer on the movable cook surface and is transferred tobeing positioned on the top surface of the external nesting rack. Themovable cook surface can include fingers and spacings between thefingers, and the external nesting rack can include support surfaces andspacings between the support surfaces, the method can further include:moving the fingers of the movable cook surface within the spacingsbetween the support surfaces as the movable cook surface is movingbetween the position within the heating chamber and the position atleast partially external to the heating chamber, wherein the item on themovable cook surface is transferred to being positioned on the topsurface of the external nesting rack as the movable cook surface ismoved at least partially recessed below the top surface of the externalnesting rack.

These and other benefits may become clearer upon making a thoroughreview and study of the following detailed description. Further, whilethe embodiments discussed above can be listed as individual embodiments,it is to be understood that the above embodiments, including allelements contained therein, can be combined in whole or in part.

BRIEF DESCRIPTION OF DRAWINGS

The technology will be better understood and features, aspects andadvantages other than those set forth above will become apparent whenconsideration is given to the following detailed description thereof.Such detailed description makes reference to the following drawings.

FIG. 1 is a perspective view of an oven with a movable cook surface,according to embodiments of the disclosure;

FIG. 2 is a plan view of the oven of FIG. 1, according to embodiments ofthe disclosure;

FIG. 3 is a front view of the oven of FIG. 1, with the oven doorpartially open, according to embodiments of the disclosure;

FIG. 4 is a perspective view of an oven in partial section with surfacesremoved for visibility, and showing aspects of the oven and a movablecook surface positioned exterior to a heating chamber, according toembodiments of the disclosure;

FIG. 5 is a side view of an oven in partial section, and showing aspectsof the oven and exemplary flow paths of heated air, according toembodiments of the disclosure;

FIG. 6 is a perspective view of an upper heat pack and a lower heat packin section, and showing an exemplary flow path of heated air, accordingto embodiments of the disclosure;

FIG. 7 is a close-up perspective view in section of a trough andresistive heating element, according to embodiments of the disclosure;

FIG. 8 is a plan view of a heat pack with the trough covers removed toshow the resistive heating elements and support structure, according toembodiments of the disclosure;

FIGS. 9-12 show alternative shapes for a trough and heating element,according to embodiments of the disclosure;

FIG. 13 is a perspective view of an exemplary vent system, according toembodiments of the disclosure;

FIG. 14 is a perspective view of an oven with surfaces removed forvisibility, and showing aspects of an exemplary system for moving amovable cook surface and an oven door, the movable cook surface beingexterior to a heating chamber and the oven door closed, the movable cooksurface being at least partially recessed below an exterior nestingrack, according to embodiments of the disclosure;

FIG. 15 is a perspective view of the oven of FIG. 14, and showingaspects of an exemplary system for moving the movable cook surface andthe oven door, the movable cook surface being partially within theheating chamber and the oven door being partially open, according toembodiments of the disclosure;

FIG. 16 is a perspective view of the oven of FIG. 14, and showingaspects of an exemplary system for moving the movable cook surface andthe oven door, the movable cook surface being completely within theheating chamber and the oven door being completely closed, according toembodiments of the disclosure;

FIG. 17 is a perspective view of an oven sowing an alternative oven doorembodiment and alternative system for moving the movable cook surfaceand the oven door, according to embodiments of the disclosure;

FIG. 18 is a perspective view of an oven having an alternative systemfor moving the movable cook surface and the oven door, wherein thenesting rack is also moved from a position below the movable cooksurface to a position at least partially above the movable cook surface,according to embodiments of the disclosure;

FIG. 19 is a perspective view of the oven of FIG. 18, and showing thenesting rack in a position at least partially above the movable cooksurface.

FIG. 20 is a close-up view of an exemplary movable cook surface andnesting rack, the movable cook surface being shown in a position wherethe movable cook surface is not yet nested with the nesting rack,according to embodiments of the disclosure; and

FIG. 21 is a close-up view of the exemplary movable cook surface andnesting rack of FIG. 20, the movable cook surface being shown in aposition where the movable cook surface is nested with the nesting rack,and positioned within the nesting rack and at least partially below thenesting rack, according to embodiments of the disclosure.

Skilled artisans will appreciate that elements in the figures areillustrated for simplicity and clarity and have not necessarily beendrawn to scale. For example, the dimensions and/or relative positioningof some of the elements in the figures may be exaggerated relative toother elements to help to improve understanding of various embodimentsof the present disclosure. Also, common but well-understood elementsthat are useful or necessary in a commercially feasible embodiment areoften not depicted in order to facilitate a less obstructed view ofthese various embodiments. It will further be appreciated that certainactions and/or steps may be described or depicted in a particular orderof occurrence while those skilled in the art will understand that suchspecificity with respect to sequence is not actually required. It willalso be understood that the terms and expressions used herein have theordinary technical meaning as is accorded to such terms and expressionsby persons skilled in the technical field as set forth above, exceptwhere different specific meanings have otherwise been set forth herein.

DETAILED DESCRIPTION OF THE EMBODIMENTS

Before any embodiments of the disclosure are explained in detail, it isto be understood that the disclosure is not limited in its applicationto the details of construction and the arrangement of components setforth in the following description or illustrated in the followingdrawings. The disclosure is capable of other embodiments and of beingpracticed or of being carried out in various ways. Also, it is to beunderstood that the use the phraseology and terminology used herein isfor the purpose of description and should not be regarded as limiting.Furthermore, the use of “right”, “left”, “front”, “back”, “upper”,“lower”, “above”, “below”, “top”, or “bottom” and variations thereofherein is for the purpose of description and should not be regarded aslimiting. The use of “including,” “comprising,” or “having” andvariations thereof herein is meant to encompass the items listedthereafter and equivalents thereof as well as additional items. Unlessspecified or limited otherwise, the terms “mounted,” “connected,”“supported,” and “coupled” and variations thereof are used broadly andencompass both direct and indirect mountings, connections, supports, andcouplings. Further, “connected” and “coupled” are not restricted tophysical or mechanical connections or couplings. As used herein, thesingular forms “a”, “an”, and “the” include plural embodiments unlessthe context clearly dictates otherwise.

As used herein, unless otherwise specified or limited, “at least one ofA, B, and C,” and the like, is meant to indicate A, or B, or C, or anycombination of A, B, and/or C. As such, these and similar phrases caninclude single or multiple instances of A, B, and/or C, and, in the casethat any of A, B, and/or C indicates a category of elements, single ormultiple instances of any of the elements of the category (orcategories).

The following discussion is presented to enable a person skilled in theart to make and use embodiments of the disclosure. Various modificationsto the illustrated embodiments will be readily apparent to those skilledin the art, and the generic principles herein can be applied to otherembodiments and applications without departing from embodiments of thedisclosure. Thus, embodiments of the disclosure are not intended to belimited to embodiments shown, but are to be accorded the widest scopeconsistent with the principles and features disclosed herein. Thefollowing detailed description is to be read with reference to thefigures, in which like elements in different figures have like referencenumerals. The figures, which are not necessarily to scale, depictselected embodiments and are not intended to limit the scope ofembodiments of the disclosure. Skilled artisans will recognize theexamples provided herein have many useful alternatives and fall withinthe scope of embodiments of the disclosure.

Referring now to FIGS. 1-3, there are depicted embodiments of an oven50. The oven 50 is defined by a housing 54 having a heating chamber 58.The housing 54, as well as the heating chamber 58, can have at least afirst oven door 62 for access to the heating chamber 58, and ingress andegress of a movable cook surface 60. The oven door 62 is shown partiallyopen in FIG. 3. The oven 50 further includes an external nesting rack 66to provide a load and unload location 67 for items 68 to be moved intothe heating chamber 58 and for items 68 coming out of the heatingchamber 58. A user interface 70 is available for a user to enter ovencontrol related data. It is to be appreciated that the conceptsdescribed herein can be incorporated within an oven having two ovendoors, such as a known conveyor oven arrangement.

In general terms, the oven 50 can include at least three primarysystems; a heating and airflow system 74, a movement system 78 formoving the movable cook surface 60 and moving the oven door 62, and acontrol system 82 to control the heating and airflow system 74 and themovement system 78. Each of these systems will be described below.

Referring to FIGS. 4-5 the oven 50 can include the heating and airflowsystem 74 to supply various forms of heat to the heating chamber 58 forheating any item or items 68, e.g., food, that have been carried intothe heating chamber 58 through the oven door 62 via the movable cooksurface 60.

In some embodiments, at least one cavity heating element 90 can heat airwithin cavity 92 for distribution to an upper air plenum 94 and a lowerair plenum 98. A motor 102, e.g., a brushless DC motor, a servo motor, astepper motor, or any known motor, can spin an air mover 106, e.g., ablower wheel such as a backward incline blower wheel, or a fan, to drawheated air from the cavity 92 through the center of the blower wheel andto expel the heated air out the perimeter of the blower wheel 106 intothe upper and/or lower air plenums 94, 98 to produce a convection ovensystem. In some embodiments, the heated air can pass through a catalyst110. The catalyst 110 serves to trigger an oxidation reduction reaction,i.e., combustion, of hydrocarbons, e.g., grease and smoke, at a lowertemperature than would naturally occur. Through this process, thehydrocarbons react with oxygen in a known process to produce heat, watervapor, and carbon dioxide.

In some embodiments, the heated air can pass through a heat pack 114. Inthe embodiment shown in FIGS. 4-5, an upper heat pack 114 and a lowerheat pack 118 are included. The flow of air through the upper and lowerplenums 94 and 98, and through the upper and lower heat packs 114 and118, can provide a closed loop air path 122 to provide the heated airconvection. It is to be appreciated that the air path 122 does not needto be a closed loop air path, and that an open loop air path is alsoenvisioned. Furthermore, in some embodiments, only an upper heat pack ora lower heat pack are included. In addition, it is to be appreciatedthat in some embodiments, no air is required to pass through the upperheat pack 114 or the lower heat pack 118, and in some embodiments, airpassing through the upper heat pack 114 or the lower heat pack 118 doesnot need to be heated.

Upper heat pack 114 and/or lower heat pack 118 can be included toprovide additional forms of heating. For example, upper heat pack 114can include an additional form of heat source, e.g., a resistive heatingelement, to supply additional heat, e.g., in the form of infraredradiation, towards any item located in the heating chamber 58.

It is to be appreciated that other heating elements, such as microwave,steam or a combination thereof, can be used instead of or in combinationwith a resistive element. It is also to be appreciated that the heatedair convection and any additional heating elements or sources can beindependently controlled by the control system 82. Upper heat pack 114and lower heat pack 118 can provide the same form of heat, or each canprovide different forms of heat. As a non-limiting example, upper heatpack 114 can provide infrared radiation, and lower heat pack 118 canprovide steam.

Referring to FIGS. 6-8, each heat pack 114, 118 is shown in section andincludes a series of generally parallel individual heat units 126, eachheat unit 126 including a trough 130, with each trough 130 having anopen gap 132 between at least a first side wall 133 and a second sidewall 135, the trough 130 forming a protective housing for at least oneresistive heating element 134. A predetermined space 128 is positionedbetween each heat unit 126 and can be adjusted to control the flow ofair between the heat units.

In some embodiments, each trough 130 can be supported on a first end 140and a second end 144 by a heat pack frame 148 (see FIG. 8). A trough 130can be generally “V” shaped, as shown, or can be other protectiveshapes, such as a “C” shape, or rectangular with an open edge, as anon-limiting examples, or any other shape to provide the protectivehousing for the resistive heating element 134. The trough 130 can alsoserve to collect debris within the heating chamber 58 from the heatingor cooking process.

In other embodiments, the troughs 130 and associated resistive heatingelements 134 can take on other arrangements besides being generallyparallel. For example, as seen in FIG. 9, the trough 152 can be spiral,and in FIG. 10 the troughs 156 can be concentric circles, and in FIG.11, the trough 160 can be serpentine shaped, and in FIG. 12, the trough164 can be a grid. Other shapes are possible based on particularapplications.

One or more connectors 170 are used to supply power to each heat pack114 and 118 (see FIG. 8). In some embodiments, upper heat pack 114 andlower heat pack 118 are the same construction with the open gap 132 ofupper heat pack 114 facing toward the heating chamber 58 and the opengap 132 of the lower heat pack 118 also facing the heating chamber 58.

Referring to FIGS. 6 and 7, the open gap 132 of trough 130 is shown witha protective cover 180. The cover 180 is shown as a metal panel with aseries of perforations 184, e.g., cuts or holes, and can also be made ofglass, quartz, or other materials, such as alloys. The cover 180 allowsthe transmission of infrared radiation, or other forms of heat, e.g.,steam, while providing the desired degree of protection for the heatingelement 134 positioned within the trough 130. It is to be appreciatedthat any shape of opening can be used in place of cuts or holes. Thecover 180 can include a first edge connector 181 and a second edgeconnector 183. The cover 180 can engage with, e.g., snap into or ontothe first side wall 133 and/or the second side wall 135 that forms theopen gap 132 of the trough 130, or can be screwed or welded or otherwiseremovably connected to the trough 130. The cover 180 can extend the fulllength of the trough 130, or the cover 130 can selectively be positionedon only portions of the trough 130.

Each heat pack 114, 118 as a unit, e.g., trough 130, heating element134, frame 148, and cover 180, can be removable for cleaning orreplacement, or in some embodiments, each heat unit 126 including trough130, resistive heating element 134 and cover 180, can be removable forcleaning or replacement.

As seen in FIG. 6, the arrangement of troughs 130 are configured todirect the forced convection air, as indicated by flow path arrows 190,from upper air plenum 94 and lower air plenum 98 around the troughs 130,and the resistive heating elements 134, and into the heating chamber 58to reduce direct contact of the resistive heating element 134 with theforced convection air 190. The forced convection air travels into theheating chamber 58 and back out of the heating chamber 58 by way of drawfrom the air mover 106, with minimal disruption to the resistive heatingelement 134 and associated infrared heat.

This diversion of the forced convection air 190 around the resistiveheating elements 134 limits the convective cooling of the resistiveheating element surface 136, thus allowing better control of the optimaltemperatures of the resistive heating element surface 136 for emissionof the desired wavelength of the infrared spectrum. In some embodiments,the surface temperature of the resistive heating element 134 iscontrolled by the control system 82, with feedback from one or moresensors 194 located in a trough 130, for example, or the sensor 194could be in the heating chamber 58, or other locations throughout theoven 50.

Each resistive heating element 134 can be sized to reach the desiredsurface temperature by a function of resistivity of the materialemployed and the voltage applied. The control system 82 can sense theapplied voltage and adjust to an equivalent voltage such thatperformance, i.e., infrared radiation, remains generally consistent overnatural voltage variations in power supplies. The control system 82 canbe used to select individual heat units 126 to turn on and to turn off.Additionally, the control system 82 can individually control the dutycycle of each heat unit 126 to control and adjust heating within theheating chamber 58 by adjusting the applied voltage.

As seen in FIG. 7, an exemplary resistive heating element 134 is shownas an open helical coil element. Other forms of a resistive heatingelement 134 can include a sheathed tubular element, a ribbon element, alight bulb, etc. The resistive heating elements 134 can be wired inparallel, series, or parallel-series.

Open coil heating elements are electrical current carrying conductorsthat should have a degree of protection from vibration, impact, and usercontact, while still allowing the desired transmission of infraredradiation. Resistive heating element support structure 200 can becoupled to either, or both, the trough 130 and the cover 180 to providestability and isolation for the resistive heating element 134. Thesupport structure 200 can include ceramic insulators, as a non-limitingexample. Other known insulation materials are possible.

When the oven door 62 is opened to access the heating chamber 58, aswitch and/or sensor 210 (see FIG. 4), coupled to the control system 82can sense the open oven door 62 and remove power from the resistiveheating element 134. Ground fault or residual current protection can beprovided by a molded case circuit breaker with this function.

To maximize the independent control by the control system 82 of aplurality of heating modes, e.g., convection air and infrared radiation,a resistive heating element of low mass is desirable. The low massmitigates overshooting a temperature set point within the heatingchamber 58.

To further mitigate overshooting a temperature set point, a ventingsystem 220 can be included. As seen in FIG. 13, at least one vent system220 is shown that includes a baffle or damper 224 that provides acontrollable path for hot air to move from the heating chamber 58 tooutside the heating chamber 58. The hot air can be vented outside theheating chamber 58 or outside the oven 50, as shown. The damper 224 canbe a rotating or sliding damper, for example. The movement of the damper224 can be controlled by a linear actuator or motor 228, for example,coupled to the control system 82, and can be based on feedback from atleast one sensor 232 (see FIG. 4) to monitor the temperature of theheating chamber 58.

Referring to FIGS. 14-16, the oven 50 can include a movement system 78for generally horizontally moving the movable cook surface 60 into andout of the heating chamber 58. The movement system 78 can also be usedto open and close the oven door 62. In some embodiments, the movementsystem 78 can both move the movable cook surface 60 and open and closethe oven door 62. In other embodiments, a first movement system can movethe movable cook surface 60, and a second movement system can open andclose the oven door 62.

In an exemplary embodiment, a drive mechanism 250 including a motor,e.g., a brushless DC motor, a servo motor, a stepper motor, or any knownmotor, can rotate a lead screw 254 creating a linear motion of acarriage 258. In some embodiments, the motion is non-linear. In someembodiments, a lead screw nut 262 can be coupled to the carriage 258 toeffect the carriage movement. In some embodiments, the carriage 258 maybe driven by a rack and pinion gear system 240 (see FIG. 17), or a guideand slide system 244 (see FIG. 18), or a worm gear system, or a cam andpulley system, all as non-limiting examples.

In some embodiments, the carriage 258 can be coupled to the movable cooksurface 60, such that movement of the carriage 258 can move the movablecook surface 60 in and out of the heating chamber 58. In someembodiments, movement of the carriage 258 can also actuate a linkagesystem 266 to actuate opening and closing of the oven door 62. In someembodiments, the carriage 258 can move along a rail 270 or other supportstructure. Bearings 274 can be included on either or both of thecarriage 258 and the rail 270 to provide a smooth controlled motion ofthe carriage 258. The movement of the movable cook surface 60 serves toprovide an auto load and unload function for item 68 placed on theexternal nesting rack 66.

The movable cook surface 60 can become at least partially recessedwithin or below a top surface 278 of the external nesting rack 66 whenthe movable cook surface 60 is extended outside of the heating chamber58 (see FIGS. 14-16 and 20-21), such that, when item 68 is on themovable cook surface 60 while the movable cook surface is in the heatingchamber, as the movable cook surface 60 extends outside the heatingchamber 58, item 68 is transferred from the movable cook surface 60 tothe top surface 278 of the external nesting rack as the movable cooksurface 60 recesses within or below the external nesting rack 66.

The external nesting rack 66 can be attached to, or placed next to, orcan be integral with the housing 54, and can be removable for cleaning,etc. The external nesting rack 66 can be stationary, or the externalnesting rack can be actuated to move into position when the movable cooksurface is exterior to the heating chamber 58, for example, when theoven door 62 is opening or closing. In some embodiments, the externalnesting rack 66 can be recessed or hidden within the oven housing 54,and can flip up or be pulled out or can be moved out by actuation of themovement system 78, as non-limiting examples.

In some embodiments, the movable cook surface 60 can be a wire rack, forexample, with fingers 280 and associated spacings 284. The externalnesting rack 66 can be arranged such that the fingers 280 of the movablecook surface 60 can move within spacings 286 between support surfaces288 of the external nesting rack 66. Because the external nesting rack66 remains exterior to the heating chamber 58, and may not be heated, itgenerally maintains a temperature closer to the ambient air temperatureoutside the oven housing 54. With the movable cook surface 60 recessedwithin or below the external nesting rack 66 (see FIGS. 16 and 21), userexposure to hot surfaces such as the movable cook surface 60 can beminimized. The support surfaces 288 can be coupled to a heat sink toquickly dissipate heat absorbed from the movable cook surface 60 or ahot item 68, for example.

In use, methods for moving an item 68 from the oven 50 can includemoving the movable cook surface 60 with the item on the movable cooksurface from a position within the heating chamber 58 to a position atleast partially external to the heating chamber; and positioning themovable cook surface 60 at least partially recessed below a top surface278 of the external nesting rack 66, such that the item 68 on themovable cook surface 60 is no longer on the movable cook surface 60 andis transferred to being positioned on the top surface 278 of theexternal nesting rack 66. The method can further include moving thefingers 280 of the movable cook surface 60 within the spacings 286between the support surfaces 288 as the movable cook surface 60 ismoving between the position within the heating chamber 58 and theposition at least partially external to the heating chamber, wherein theitem 68 on the movable cook surface 60 is transferred to beingpositioned on the top surface 278 of the external nesting rack 66 as themovable cook surface 60 is moved at least partially recessed below thetop surface 278 of the external nesting rack 66.

The method can further include moving the item 68 into the heatingchamber 58 by moving the movable cook surface 60 from the position atleast partially recessed below the top surface 278 of the externalnesting rack 66, to the position within the heating chamber 58, suchthat the item 68 on the top surface 278 of the external nesting rack 66is transferred to being positioned on the movable cook surface 60 and isno longer on the external nesting rack 66.

As a non-limiting example of a linkage system 266, as the carriage 258and an associated carriage link arm 294 travels towards the heatingchamber 58, an oven door timing linkage assembly 298 can push on a lowerdoor arm 302 (in some embodiments this can be a parallel bar assembly),which can cause the oven door 62 to open. The geometry of the lower doorarm 302 can pivot and the oven door timing linkage assembly 298 can bepositioned to open the oven door 62 to allow the movable cook surface 60to enter the heating chamber 58. When the oven door timing linkageassembly 298 passes a predetermined vertical position, for example, themotion of the oven door 62 can be reversed, thus closing the oven door62 as the movable cook surface 60 completes its travel motion into theheating chamber 58. The operation of the drive mechanism 250 can bereversed so as to reverse the motion of the carriage 258 to open theoven door 62 and move the movable cook surface 60 to a position outsidethe heating chamber 58 and nested or otherwise positioned within orbelow the exterior nesting rack 66.

FIGS. 14-16 primarily show the door 62 is lifted vertically in agenerally vertical plane. Other possible door arraignments include, butare not limited to, hinging on any side (left, right, top, or bottom)and pivoting to allow the carriage 258 to enter and exit the heatingchamber 58. A double door, i.e., a French door style opening and closingarrangement is also possible. The oven door 62 may also open and closealong an arcuate path, as seen in FIG. 17

Timing of the door 62 movement can be controlled by geometric design ofthe movement system 78, and specifically by the linkage system 266. Itis to be appreciated that other arrangements, such as a cam system,chain, screw drive, timing belt, or other means coupled with anelectronic control system, sensors, motors, actuators, and gears, can beused to control the timing of the oven door 62, to allow the oven doorto open and close to clear a maximum height H allowed by the height ofthe heating chamber 58.

Although the movable cook surface 60 is described as being moved by amotor, it is to be appreciated that the movable cook surface 60, eitheralone or in unison with the oven door 62, can also be moved manually viaa lever system or by a variety of other motorized or non-motorizedlinkage movement designs, including a counterbalance system, e.g., withweights and springs. As seen in FIG. 17, a handle 304 can be included onthe oven door 62 to manually open and close the oven door, and move themovable cook surface 60 into and out of the heating chamber 58.

The oven 50 can include control system 82. In some embodiments,operating parameters for the oven 50 to cook any items 68 placed on themovable cook surface 60 to be carried into the heating chamber 58through the oven door 62 can be entered at a user interface controlpanel 70.

The user interface 70 can be implemented with a touch screen, althoughit can also be implemented with a keypad and liquid crystal display(LCD), switches, and/or dials, as non-limiting examples. An operator canenter commands, such as mode of operations, cooking temperatures withinthe heating chamber 58, specific heating elements to be used, cookingtimes, air mover speeds, venting, etc., via the user interface 70 toeffectuate cooking controls on any items placed within the heatingchamber 58. The user interface 70 can be associated with a non-volatilememory for storing various cooking instructions, such as cook times,cook temperatures and blower speeds, for different items under the namesor graphical representations of corresponding items.

At least one sensor 320 (see FIG. 4), such as a thermocouple, can becoupled to the control system 82 and can be positioned in variouslocations within the oven housing to measure temperature and otherenvironmental conditions, e.g., humidity, and provide the measured datato the control system. In addition, sensor 232 and sensor 194 can becoupled to the control system 82 to provide additional measurements oftemperature and other environmental conditions.

For the avoidance of doubt, aspects of the present disclosure describedwith respect to the systems are applicable to the methods and aspectsdescribed with respect to the methods are applicable to the systems.

The present disclosure describes embodiments with reference to theFigures, in which like numbers represent the same or similar elements.Reference throughout this specification to “one embodiment,” “anembodiment,” or similar language means that a particular feature,structure, or characteristic described in connection with the embodimentis included in at least one embodiment of the present disclosure. Thus,appearances of the phrases “in one embodiment,” “in an embodiment,” andsimilar language throughout this specification may, but do notnecessarily, all refer to the same embodiment.

The described features, structures, or characteristics of theembodiments may be combined in any suitable manner in one or moreembodiments. In the description, numerous specific details are recitedto provide a thorough understanding of embodiments of the disclosure.One skilled in the relevant art will recognize, however, that theembodiments may be practiced without one or more of the specificdetails, or with other methods, components, materials, and so forth. Inother instances, well-known structures, materials, or operations are notshown or described in detail to avoid obscuring aspects of thedisclosure.

Although the above discussion discloses various exemplary embodiments ofthe disclosure, it should be apparent that those skilled in the art canmake various modifications that will achieve some of the advantages ofthe disclosure without departing from the true scope of the disclosure.

We claim:
 1. An oven comprising: a housing; a heating chamber positionedwithin the housing; at least one oven door to provide access to theheating chamber; an external nesting rack positionable on or near thehousing; and a movable cook surface, the movable cook surface movablebetween a position within the heating chamber and a position at leastpartially external to the heating chamber, such that when the movablecook surface is in the position at least partially external to theheating chamber, the movable cook surface is positioned at leastpartially recessed below a top surface of the external nesting rack. 2.The oven according to claim 1, wherein the at least partially recessedmovable cook surface is positioned within the external nesting rack. 3.The oven according to claim 1, wherein the movable cook surface includesfingers and spacings between the fingers.
 4. The oven according to claim3, wherein the external nesting rack includes support surfaces andspacings between the support surfaces.
 5. The oven according to claim 4,wherein the fingers of the movable cook surface move within the spacingsbetween the support surfaces as the movable cook surface is movingbetween the position within the heating chamber and the position atleast partially external to the heating chamber.
 6. The oven accordingto claim 1, wherein the external nesting rack is removably coupled tothe housing.
 7. The oven according to claim 1, wherein the externalnesting rack moves from a position below the movable cook surface to aposition at least partially above the movable cook surface, such thatthe top surface of the external nesting rack is above the movable cooksurface.
 8. The oven according to claim 1, wherein the heating elementheats air within a cavity for distribution to an upper air plenum and alower air plenum.
 9. The oven according to claim 1, further including afirst heating element to provide a first method of heating.
 10. The ovenaccording to claim 9, wherein the first method of heating providesheated air convection to the heating chamber.
 11. The oven according toclaim 10, further including a second heating element to provide a secondmethod of heating, the second method of heating different than the firstmethod of heating.
 12. The oven according to claim 11, wherein thesecond method of heating provide infrared heating to the heatingchamber.
 13. The oven according to claim 12, further including a userinterface, the user interface to allow individual control of the firstmethod of heating and the second method of heating.
 14. A heat pack foruse in an oven, the heat pack comprising: at least one heat unit, theheat unit including a trough, the trough including an open gap betweenat least a first side wall and a second side wall, the trough forming aprotective housing for at least one heating element positioned withinthe trough; a cover, the cover positioned on the open gap, the coverincluding a first edge connector and a second edge connector, the firstedge connector to engage with the first side wall and the second edgeconnector to engage with the second side wall, the cover including aseries of perforations; and heating element support structure, theheating element support structure coupled to at least one of the troughand the cover, the heating element support structure to isolate the atleast one heating element from the trough and the cover.
 15. The heatpack according to claim 13, wherein the at least one heating element isa resistive heating element to provide infrared heat.
 16. The heat packaccording to claim 13, wherein the at least one heating element is atleast one of an open coil resistive heating element, a sheathed tubularresistive element, a ribbon resistive heating element, and an infraredheating lightbulb.
 17. The heat pack according to claim 13, wherein theheating element support structure is a ceramic material.
 18. The heatpack according to claim 13, wherein the heat unit is substantiallystraight.
 19. The heat pack according to claim 13, further including aplurality of heat units, each heat unit being generally parallel to eachother with a predetermined space between each heat unit; and a frame,the frame to support a first end of each of the plurality of the heatunits and a second end of each of the plurality of the heat units. 20.The heat pack according to claim 19, wherein each of the plurality ofheat units are individually controllable by a control system.
 21. Anoven comprising: a housing; a heating chamber positioned within thehousing; at least one oven door to provide access to the heatingchamber; at least one heating element to heat air in a cavity within thehousing for distribution to an upper air plenum and a lower air plenumto provide a heated air convection; a cook surface positioned in theheating chamber, the cook surface to support an item for heating withinthe heating chamber; an upper heat pack positioned between the upper airplenum and the cook surface to direct infrared heat downward into theheating chamber; a lower heat pack positioned between the lower airplenum and the cook surface to direct infrared heat upward into theheating chamber; the upper heat pack including a plurality of upper heatunits supported by an upper frame and being generally parallel to eachother with a predetermined space between each upper heat unit, eachupper heat unit including an upper heat unit trough, the upper heat unittrough including an open gap between at least a first side wall and asecond side wall, the upper heat unit trough forming a protectivehousing for at least one upper heat unit resistive heating elementpositioned within the upper heat unit trough and supported by an upperheat unit heating element support structure, and an upper heat unitcover positioned on the open gap, the upper heat unit cover including aseries of perforations; the lower heat pack including a plurality oflower heat units supported by a lower frame and being generally parallelto each other with a predetermined space between each lower heat unit,each lower heat unit including a lower heat unit trough, the lower heatunit trough including an open gap between at least a first side wall anda second side wall, the lower heat unit trough forming a protectivehousing for at least one lower heat unit resistive heating elementpositioned within the lower heat unit trough and supported by a lowerheat unit heating element support structure, and a lower heat unit coverpositioned on the open gap, the lower heat unit cover including a seriesof perforations; wherein the heated air passes through the upper airplenum and the predetermined space between each upper heat unit and intothe heating chamber such that a flow path of the heated air conventionis directed to avoid contact with the upper heat unit resistive heatingelement positioned within the upper heat unit trough; and wherein theheated air passes through the lower air plenum and the predeterminedspace between each lower heat unit and into the heating chamber suchthat the flow path of the heated air convention is directed to avoidcontact with the lower heat unit resistive heating element positionedwithin the lower heat unit trough.
 22. The oven according to claim 21,further including a user interface, the user interface to allowindividual control of the upper heat pack and the lower heat pack. 23.The oven according to claim 22, wherein the user interface furtherallows individual control of each upper heat unit in the upper heat packand each lower heat unit in the lower heat pack.
 24. The oven accordingto claim 21, wherein the upper heat unit cover includes a first edgeconnector and a second edge connector, the first edge connector toengage with the first side wall of the upper heat unit trough and thesecond edge connector to engage with the second side wall of the upperheat unit trough; and the lower heat unit cover includes a first edgeconnector and a second edge connector, the first edge connector toengage with the first side wall of the lower heat unit trough and thesecond edge connector to engage with the second side wall of the lowerheat unit trough.
 25. The oven according to claim 21, wherein the upperheat unit heating element support structure is coupled to at least oneof the upper heat unit trough and the upper heat unit cover, the upperheat unit heating element support structure to isolate the at least oneupper heat unit heating element from the upper heat unit trough and theupper heat unit cover; and the lower heat unit heating element supportstructure is coupled to at least one of the lower heat unit trough andthe lower heat unit cover, the lower heat unit heating element supportstructure to isolate the at least one lower heat unit heating elementfrom the lower heat unit trough and the lower heat unit cover.
 26. Theoven according to claim 21, wherein the upper heat unit resistiveheating element is at least one of an open coil resistive heatingelement, a sheathed tubular resistive element, a ribbon resistiveheating element, and an infrared heating lightbulb; and the lower heatunit resistive heating element is at least one of an open coil resistiveheating element, a sheathed tubular resistive element, a ribbonresistive heating element, and an infrared heating lightbulb.
 27. Theoven according to claim 21, wherein the upper heat unit heating elementsupport structure is a ceramic material; and the lower heat unit heatingelement support structure is a ceramic material.
 28. The oven accordingto claim 21, further including an external nesting rack positionable onor near the housing; and the cook surface being movable, the movablecook surface movable between a position within the heating chamber and aposition at least partially external to the heating chamber, such thatwhen the movable cook surface is in the position at least partiallyexternal to the heating chamber, the movable cook surface is positionedat least partially recessed below a top surface of the external nestingrack.
 29. The oven according to claim 28, further including a movementsystem to move the movable cook surface.
 30. A method for moving an itemfrom an oven, the oven comprising a housing, a heating chamberpositioned within the housing, at least one oven door to provide accessto the heating chamber, an external nesting rack positionable on or nearthe housing, and a movable cook surface, the method comprising the stepsof: moving the movable cook surface with the item on the movable cooksurface from a position within the heating chamber to a position atleast partially external to the heating chamber; and positioning themovable cook surface at least partially recessed below a top surface ofthe external nesting rack, such that the item on the movable cooksurface is no longer on the movable cook surface and is transferred tobeing positioned on the top surface of the external nesting rack. 31.The method according to claim 30, wherein the movable cook surfaceincludes fingers and spacings between the fingers, and the externalnesting rack includes support surfaces and spacings between the supportsurfaces, the method further comprising: moving the fingers of themovable cook surface within the spacings between the support surfaces asthe movable cook surface is moving between the position within theheating chamber and the position at least partially external to theheating chamber, wherein the item on the movable cook surface istransferred to being positioned on the top surface of the externalnesting rack as the movable cook surface is moved at least partiallyrecessed below the top surface of the external nesting rack.